JPH02131803A - Wear-resistant cermet cutting tool with excellent fracture resistance - Google Patents

Abstract

(57) [Abstract] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed Description of the Invention] [Field of Industrial Application] This invention provides excellent durability when used for interrupted cutting of steel etc. under particularly severe conditions and heavy cutting such as high feed and high depth of cut. The present invention relates to a cermet cutting tool that exhibits breakability and has excellent wear resistance.

[Conventional technology]

Conventionally, as described in, for example, JP-A-54-H9815, one or two of Co and Ni are used as binder phase forming components in weight% (hereinafter % indicates weight%). Composite carbonitride [hereinafter referred to as (
A cermet cutting tool is known, which has a composition consisting of TiM)CN] and non-nJ impurities, and has a hard surface layer formed on the surface, with the outermost surface having the highest hardness. ,
This cermet cutting tool exhibits excellent wear resistance when used for high-speed cutting of steel, etc., and furthermore, this cermet cutting tool can be used to sinter a green compact with a predetermined composition, such as carbon dioxide or carbon dioxide. In a carburizing atmosphere containing CH4 etc., the temperature is raised to a predetermined temperature below the liquid phase appearance temperature, and then,
It is also well known that the material is manufactured by raising the temperature to the sintering holding start temperature and performing the period from there to the sintering holding end temperature at least in a vacuum atmosphere.

[Problem to be solved by the invention]

However, although the conventional cermet cutting tools mentioned above exhibit excellent wear resistance in high-speed cutting of steel,
When this is used for interrupted cutting or heavy cutting that requires toughness and impact resistance, breakage and chipping occur on the cutting edge, making it impossible to put it to practical use.

[Means to solve the problem]

Therefore, the present inventors focused on the above-mentioned conventional cermet cutting tools, and conducted research in order to provide them with excellent chipping resistance while maintaining their excellent tangle resistance. , when manufacturing a cermet cutting tool, a green compact having a predetermined compounding composition is heated to (a) a predetermined temperature (hereinafter referred to as the first (b) From the first heating temperature to a predetermined temperature above the liquid phase appearance temperature (hereinafter referred to as the second heating temperature) (C) Then, the temperature is increased to at least the second temperature increase using either a denitrifying atmosphere such as a vacuum, a decarburizing atmosphere such as a CO2 gas-containing atmosphere, or both atmospheres. A nitrogen atmosphere is provided between the temperature rise from to the sintering retention start temperature and the sintering retention end temperature, (d) cooling is performed in a non-oxidizing atmosphere, (e) and from the sintering retention end temperature, Cooling at a cooling rate of 30° C./sin or less until at least the temperature at which the liquid phase changes to a solid phase and the liquid phase disappears.
When sintered under the conditions (a) to (e) above, the maximum hardness in the cross section of the tool is at a depth within a range of 2 to 50 m from the outermost surface, and the outermost surface is 60 to 90 m below the maximum hardness. %
A cermet cutting tool having a hard surface layer having a hardness corresponding to Excellent fracture resistance is ensured by the outermost surface having a
Excellent wear resistance is ensured by the maximum hardness at a depth within the range of ~50 μm, and it can be used not only in high-speed cutting but also in interrupted cutting and heavy cutting without chipping or chipping. They obtained the knowledge that the improved performance can be demonstrated over a long period of time.

This invention was made based on the above knowledge, and contains H containing one or two of Co and Ni as binder phase forming components = 5 to 30%, and the remainder is a dispersed phase forming component. as N/(C0N
) having an atomic ratio: 0.3 to 0.7 ((Ti.M
)CN) and unavoidable impurities, and the maximum hardness in the cross section of the tool is at a depth within the range of 2 to 50 degrees from the outermost surface, and the outermost surface is 60 to 90 degrees below the maximum hardness. The cutting tool is characterized by a wear-resistant cermet cutting tool with excellent chipping resistance and a hard surface layer having a hardness equivalent to 50%.

Next, the reason why the numerical conditions are limited as described above in the cermet cutting tool of the present invention will be explained.

(a) Content of Co and Ni These components have the effect of improving the toughness of the tool, but if the content is less than 5%, the desired high toughness cannot be secured; If it exceeds 30%, the hardness decreases and the wear resistance decreases, so the content was determined to be 5 to 3096.

(b) N/(C+N) atomic ratio of (Ti,M)CN The relative proportions of C and N in (Ti,M)CN affect the sinterability of the cermet and the hardness distribution of the tool. If the atomic ratio is less than 0.3, the NEI will be too small relative to the amount of C, and in this case, the maximum hardness will shift toward the outermost surface in relation to the sintering conditions. Therefore, it is no longer possible to maintain the maximum hardness at a depth within the range of 2 to 501 lIm.On the other hand, when the atomic ratio exceeds 0.7, on the other hand, there is too much Nffi, which causes poor sinterability. decreases, making it impossible to secure the desired high toughness, so the atomic ratio is reduced to 0.
．． It was determined to be 3 to 0.7.

(c) Depth position of maximum hardness If the depth position is shallower than 2 μm, the desired fracture resistance cannot be secured, whereas if the depth position is deeper than 50 μm, the hardness is due to the surface hard layer. Since the wear of the cutting edge progresses too much before the effect of improving wear resistance appears and the cutting performance deteriorates, the depth position was determined to be 2 to 501 IM.

(d) Top surface hardness If the top surface hardness exceeds the hardness equivalent to 90% of the maximum hardness, the difference in hardness between the maximum hardness and the top surface hardness is too small to ensure the desired fracture resistance. On the other hand, if the hardness of the outermost surface becomes less than 60% of the maximum hardness, the progress of the outermost surface becomes faster and the tool life becomes shorter. The outermost surface hardness is the highest hardness of 60 to 90
It was determined that the hardness corresponds to %.

Note that the depth position of the maximum hardness in the surface hard layer of the cermet cutting tool of this invention is mainly (Ti, M)CN
It can be adjusted by adjusting the N/(C+N) atomic ratio of N/(C+N) and sintering conditions, for example, N/(C+N
) as the value of In the heating process, the degree of decarburization and denitrification can be increased by slowing down the heating rate in a decarburizing atmosphere or denitrifying atmosphere from the first heating temperature to the second heating temperature, or holding it during the heating process. Then, the maximum hardness position moves inward of the tool, and conversely, when the degree of decarburization and denitrification is reduced, it moves to the outermost surface side, and in this case, the outermost surface hardness also changes according to the movement of the maximum hardness. As a natural result of this, the closer the highest hardness position is to the outermost surface, the higher the outermost surface hardness becomes.

〔Example〕

Next, the cermet cutting tool of the present invention will be specifically explained using examples.

As a raw material powder, all 1~! ．． TiC powder, TiN powder, wc powder, M O 2 C powder, TaC powder, NbC having a predetermined average particle size within the range of 5IIta.
powder, HfC powder, ZrC powder, Co powder, and Nl
Powders were prepared, these raw material powders were blended into the composition shown in Table 1, wet mixed in a ball mill for 72 hours, dried, and then mixed according to ISO standard S NM (; 1203
08, and then these green compacts are: (a) heated from room temperature to 1100°C (first heating temperature) in a vacuum atmosphere of 10'torr; (b) 1
tot from 100℃ to 1350℃ (second temperature increase)
orr in a C O 2 gas atmosphere, (e)
Raising the temperature from 1350°C to 1450°C (sintering holding start temperature), holding this sintering temperature for 1 hour, and cooling from the sintering temperature to room temperature in a nitrogen atmosphere of IOLorr, (d) and By sintering under the conditions (a) to (d) above, cooling from the sintering temperature to 1200°C in the cooling process of (e) above is performed at a cooling rate of 15°C/1 inch. Cutting tools 1 to 13 made of cermet of the present invention having the characteristics shown in the table were manufactured, and for the purpose of comparison, the above green compacts were (1) heated under 100 torr of CO from room temperature to 1250°C.
(2) Raise the temperature from 1250 °C to 1450 °C (sintering holding start temperature), hold this sintering temperature for 1 hour, and cool from the sintering temperature to room temperature using IO. By sintering under the conditions (+) and (2) above in a vacuum atmosphere of -2Lorr,
Conventional cermet cutting tools 1 to 13 having the characteristics shown in Table 1 were also manufactured.

In the above example, a case was described in which single component carbide and nitride were used as the raw material powder, but single component carbonitride, multiple component composite carbide solid solution, composite nitride solid solution, and composite carbon Of course, a nitride solid solution may also be used.

Next, for the purpose of evaluating the fracture resistance of the various cermet cutting tools obtained as a result, the work material: JI
S-SNCM439 (hardness: 11B270) square material, cutting speed 2150 m/sin. Depth of cut = 3m■, Feed = 0.5 dragon/rev. A dry interrupted cutting test was conducted on steel under the conditions of , cutting time: 5 minutes, and the number of cutting edges that were damaged out of 10 tested cutting edges was measured.In order to further evaluate the wear resistance, Material: JIS-SNCM439 (Hardness: Ha
270) round bar, cutting speed: 300 m/sin
A dry continuous high-speed cutting test was conducted on steel under the following conditions: depth of cut: 2 mm x feed: 0.3 +111, cutting time: 20 minutes, and the flank wear width of the cutting edge was measured. These results are shown in Table 1.

[Effects of the Invention] From the results shown in Table 1, the cermet cutting tools 1 to 1 of the present invention in which the maximum hardness exists at a predetermined depth inward from the outermost surface
No. 3 exhibited excellent wear resistance equivalent to conventional cermet cutting tools No. 1 to No. 13, in which the maximum hardness is present on the outermost surface, and exhibited even better fracture resistance than this, making it an excellent cutting tool. It is clear that the performance is demonstrated.

As mentioned above, the cermet cutting tool of the present invention has excellent fracture resistance, so when used for interrupted cutting of steel etc. under severe conditions, flea cutting at high feed rate and high depth of cut, etc. Not only does it exhibit excellent cutting performance, but it also has excellent wear resistance, so when used for high-speed cutting of steel etc., it exhibits excellent performance for an extremely long period of time, making it suitable for industrial use. It brings about a great effect.

Claims (1)

[Claims] (1) Contains 5 to 30% by weight of one or two of Co and Ni as a binder phase forming component, and the remainder is N/(C+N) atomic ratio of 0.3 to 0.3 as a dispersed phase forming component. 0
．． 7 and one or more of W, Mo, Ta, Nb, Hr, and Zr, and unavoidable impurities, and has the highest hardness in the tool cross section. 2 to 50μ below the outermost surface
Abrasion resistance with excellent chipping resistance, characterized by having a hard surface layer located at a depth within the range of m, and further having a hard surface layer whose outermost surface has a hardness equivalent to 60 to 90% of the maximum hardness. Cermet cutting tool.